KR20190131873A - Air Quality Management Equipment by Vegetation - Google Patents

Abstract

The present invention relates to an air quality management apparatus using plants. The built-in air quality management apparatus for managing air quality with plants includes: M port insertion parts inserting and fixing M (M>=4) port modules, which include a frame part maintaining a hexagonal structure, a storage part storing leaf and stem parts of a designated plant while exposing the leaf part to the outside, and a body part storing a root part of the plant, by placing the modules in a designated placement structure; a discharge part discharging indoor air to the outside; a housing part sealing parts except the discharge part and the M port insertion parts by blocking the flow of air from the outside; a fan part generating positive pressure for discharging the indoor air to the outside through the discharge part while creating negative pressure for taking outdoor air into the housing part via the M port modules inserted in the M port insertion parts; a light source part emitting visible light of at least one light intensity range to the leaf part of the plant, stored in the M port modules inserted in the M port insertion parts, outside the housing part; a water tank part storing a designated volume of water; a pump part pumping the water stored in the water tank part up to a designated height; and a water supply part dropping a designated volume of water per unit time to supply the water to a designated number of the uppermost port modules of the M port modules inserted in the M port insertion parts by using potential energy of the water pumped through the pump part.

Description

Air Quality Management Equipment using Plants {Air Quality Management Equipment by Vegetation}

The present invention relates to a wall-type air quality management device for managing the air quality by using a plant, the frame portion for maintaining the hexagonal structure and the receiving portion for exposing the leaf portion to the outside while receiving the leaf portion and the stem portion of the designated plant and the M port insertion parts for placing and fixing M (M≥4) port modules manufactured by including a body part for accommodating the root part of the plant in a designated arrangement structure, a discharge part for discharging the air inside to the outside, In addition to the discharge portion and the M port inserting portion, the outside air flows into the housing portion through the housing portion which blocks and seals the flow of air to the outside, and the M port modules inserted into the M port inserting portions. A fan unit for generating a positive pressure for discharging the internal air to the outside through the discharge unit while generating a negative pressure for the discharge unit; A light source unit for irradiating visible light of at least one specified brightness range to a leaf portion of a plant accommodated in M port modules inserted into the M port insertion units from an outside of the housing, a water tank unit for storing a specified volume of water, and A pump unit for pumping the water stored in the tank to a specified height, and a specified number of port modules provided on the uppermost layer of the M port modules inserted into the M port insertion units by using the potential energy of the water pumped through the pump unit The present invention relates to an air quality management apparatus including a water supply unit configured to drop supply a predetermined volume of water per unit time.

Recently, there is increasing interest in indoor environments where people living in cities spend more than 90% of their daily lives. In particular, as air pollution, such as fine dust and yellow dust, becomes serious, comfort for the indoor air environment is becoming important.

However, in contrast to the concern for indoor air environment (such as fine dust and harmful substances), improvement measures for the indoor environment and the air environment of public facilities rely only on the removal of fine dust such as air cleaner or ventilation system operation. In addition, the use of specialized air cleaning equipment is expensive, or poor management can cause new pollutants can not be a fundamental solution.

Korean Unexamined Patent Publication No. 10-2016-0148170 (December 26, 2016) relates to an environment-friendly air purification system using air purification plants and mineral filters, and includes a growth medium capable of passing air and planting plants. It has a configuration including a air filter plant planted in the growth medium, a water supply unit for supplying water to the air passing through the growth medium, and a mineral filter disposed to filter the fine dust contained in the air passing through the growth medium; have.

However, the growth medium is a kind of soil, and there is a possibility that harmful microorganisms or other microorganisms floating in the air may be deposited and multiply in addition to microorganisms that are beneficial for controlling air quality. There is no choice but to exist.

An object of the present invention for solving the above problems is a port module which is inserted into the pot inserting portion formed on the wall surface of the wall-type air quality management device for managing the air quality using a plant, Instead of growth medium, there is provided a port module for accommodating designated n (n ≧ 2) rock grains (for example, ganbanite, pearlite, volcanic stone, porous ceramic balls, etc.) and activated carbon, which are formulated at a predetermined mixing ratio.

Wall-type air quality management device for managing the air quality by using the plant according to the present invention, the frame portion for maintaining the hexagonal structure and the receiving portion and the plant to expose the leaf portion to the outside while receiving the leaf portion and the stem portion of the designated plant M port inserting parts for arranging and inserting M (M≥4) port modules manufactured by a specified arrangement structure, including a body part for accommodating the root part of the discharge part, a discharge part for discharging the air inside to the outside, and In addition to the discharge portion and the M port insertion portion, a housing portion for blocking and sealing air flow to the outside, and M port modules inserted into the M port insertion portion for introducing external air into the housing portion A fan unit for generating a positive pressure for discharging the internal air to the outside through the discharge unit while generating a negative pressure, and the housing unit A light source unit for irradiating visible light of at least one specified brightness range to a leaf portion of a plant accommodated in M port modules inserted into the M port insertion units from outside, a water tank unit for storing a specified volume of water, and the water tank unit A pump unit for pumping the water stored in the pump to a specified height, and using a potential energy of the water pumped through the pump unit M port module inserted into the M port insertion unit of the designated number of port modules provided on the top floor unit It may be configured to include a water supply for drop-feeding a predetermined volume of water per hour.

According to the present invention, the air quality management device may further comprise a drip tray that receives the water discharged through the specified number of port modules provided in the lowermost layer of the M port module and delivered to the water tank unit.

In addition, it may further comprise a backflow prevention unit for preventing the backflow of water stored in the tank.

According to the present invention, the air quality management device comprises a sensor unit including i (i≥1) sensors for sensing the quality of the outside air, and based on the result of sensing the quality of the outside air through the sensor unit It may further comprise a control module for controlling to irradiate visible light in a specified brightness range through the light source unit.

According to the present invention, the control module checks whether the CO2 detection amount sensed by the sensor unit exceeds a preset reference value, and when the detected CO2 detection amount exceeds a preset reference value, the control module is discharged through the light source unit to designate the arrangement. The luminous intensity range of visible light reaching the leaf portion of the plant housed in each port module arranged in the structure can be controlled to maintain the luminous intensity range of 1,000 lux or more.

According to the present invention, the control module emits light through the light source unit and maintains the photosynthesis holding time at which the visible light of the luminous intensity range of 1,000 lux or more is irradiated to the leaf part of the plant accommodated in each port module arranged in the designated arrangement time. Check whether the amount of CO2 detection exceeded or detected by the sensor unit is less than a preset reference value, and if the photosynthesis holding time exceeds a preset reference time or the detected CO2 detection amount is less than a preset reference value, the light is emitted through the light source unit. Thus, the luminance range of the visible light reaching the leaf portion of the plant accommodated in each port module arranged in the designated arrangement structure can be controlled to maintain the luminance range of 700 lux or less.

According to the present invention, the air quality management device comprises a sensor unit including i (i≥1) sensors for sensing the quality of the outside air, and based on the result of sensing the quality of the outside air through the sensor unit It may further comprise a control module for controlling the intensity of the sound pressure or positive pressure generated by the fan unit to a specified intensity.

According to the present invention, the i sensors include a gas sensor for detecting CO2, a gas sensor for detecting CO, a gas sensor for detecting NO, a gas sensor for detecting NO2, a gas sensor for detecting SO2, and an O3 for detecting O2. Gas sensor, VOC sensor to detect VOC (Volatile Organic Compounds), fine dust sensor to detect fine dust, temperature sensor to detect temperature, humidity sensor to detect humidity, sound sensor to detect sound, light to detect brightness It may comprise one or more of the sensors.

According to the present invention, the frame portion of the port module is made of a hexagonal structure and implements a hexagonal structure in which one lowermost vertex is disposed in the direction of gravity among the six vertices of the hexagonal structure, and the accommodating portion of the port module is hexagonal. It is provided in one side direction of the frame portion in which the hole of the structure is formed to form an accommodating space of the leading shape based on the lowermost vertex of the hexagonal structure and is exposed to the outside of the housing portion when inserted into the port insertion portion, The body portion is provided in the other side surface direction of the frame portion in which the hexagonal structure hole is formed, and forms a receiving space having a pentagonal cross-sectional structure based on the lowest vertex of the hexagonal structure and gravity at one or more surface regions forming the receiving space. A plurality of perforated discharge holes aligned in a direction matching the direction vector component and inserted into the port insert It may be accommodated in the housing part at the time of entrance.

According to the present invention, the accommodating part may include a plurality of suction holes for sucking the air outside the air quality controlling device into the accommodating space of the accommodating part by using a sound pressure formed in the internal space of the air quality managing device. have.

According to the present invention, the suction hole is a unit time through the designated number of port modules in response to the sound pressure generated through the fan unit provided in the air quality management device when a predetermined number of port modules are inserted into the wall of the air quality management device. It can be made to include the size and number that can be introduced into the air of the specified volume per sugar.

According to the present invention, the receiving portion may accommodate the designated n (n ≧ 2) rock grains and activated carbon, which are blended at a predetermined mixing ratio instead of soil.

According to the present invention, the body portion, instead of the soil can be accommodated in the specified n (n ≥ 2) of the rock granules and activated carbon blended at a predetermined mixing ratio.

According to the present invention, the n kinds of rocks may include elvan, pearlite, volcanic stone, and porous ceramic balls.

According to the invention, the n kinds of rock granules and activated carbon, the size of the irregular shape of 5mm (± 2mm) diameter, the size of the irregular shape of 10mm (± 5mm) diameter, the size of the irregular shape of 20mm (± 5mm) diameter It may comprise at least one or a combination of two or more of the size of the irregular shape of 30mm (± 5mm) in diameter.

According to the present invention, the n kinds of rock granules and activated carbon have a predetermined number of ports corresponding to a sound pressure generated through a fan provided in the air quality management apparatus when a predetermined number of port modules are inserted into a wall of the air quality management apparatus. It can be made to include the size of the shape capable of forming a void for introducing a specified volume of outside air per unit time through the module.

According to the present invention, the discharge hole may include a plurality of discharge holes which are aligned and aligned in a direction matched with the gravity direction vector component on both bottom surfaces of the pentagonal cross-sectional structure forming the accommodation space of the body portion. .

According to the present invention, the gravity direction vector component may include a direction perpendicular to the lowermost corner region of the pentagonal cross-sectional structure forming the accommodation space of the body portion.

According to the present invention, the body portion, the flow path groove forming a flow path for guiding the water discharged through the discharge hole in a direction matching the gravity direction vector component in the outer surface area of the body portion having the discharge hole It may be made to include more.

According to the present invention, the body portion is sucked through the suction hole of the accommodation portion in both side regions or the rear region of the pentagonal cross-sectional structure forming the accommodation space of the body portion via the accommodation space and the accommodation space of the body portion. It may further comprise a discharge hole for discharging the air into the air quality management device.

According to the present invention, the port module is separated from the body portion or coupled in an upward direction and forms a structure that matches the hexagonal structure of the frame portion when coupled to the body portion and the water falling in the gravity direction in the upper direction is It may further comprise a cover portion of the upper structure is opened to fall in the receiving space of the body portion.

According to the present invention, the cover portion, when coupled to the body portion further comprises a blocking membrane portion to prevent the outside air flowing directly into the interior of the air quality management device through the hole of the hexagonal structure of the preliminary portion in the area in contact with the frame portion. It can be made, including.

According to the present invention, instead of the conventional soil or growth medium, the designated n (n≥2) rock grains (for example, ganbanite, pearlite, volcanic stone, porous ceramic balls, etc.) and activated carbon formulated at a predetermined mixing ratio are accommodated. Port modules that provide excellent air cleaning, air humidity, fresh air production, allergens, and allergy free components, eliminating the need for separate filters and reducing the cost and time required for filter replacement and management. There is an advantage to save.

1 is a view showing the configuration of an air quality control apparatus using a plant according to an embodiment of the present invention.
2 is a view showing the configuration of a port module for air quality management according to an embodiment of the present invention.
3 is a diagram constitutively illustrating a port module manufacturing process for air quality management according to an embodiment of the present invention.
4 is an exemplary view of an air quality management apparatus according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings and description will be described in detail the operating principle of the preferred embodiment of the present invention. However, the drawings and the following description shown below are for the preferred method among various methods for effectively explaining the features of the present invention, the present invention is not limited only to the drawings and description below.

That is, the following embodiments correspond to embodiments of the preferred union form among many embodiments of the present invention, and embodiments or omit specific configurations (or steps) in the following embodiments. An embodiment of dividing a function implemented in a specific configuration (or step), or an embodiment, a specific configuration (or step) incorporating a function implemented in two or more configurations (or steps) into one configuration (or step). Embodiments to replace the order of operation, etc., unless explicitly stated otherwise in the following examples will be apparent that all belong to the scope of the present invention. Therefore, it is to be noted that various embodiments corresponding to a subset or a filter based on the following examples may be divided retrospectively according to the filing date of the present invention.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the present invention.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for efficiently explaining the technical spirit of the present invention to those skilled in the art to which the present invention pertains. It is only.

1 is a view showing the configuration of the air quality management apparatus using plants according to the embodiment of the present invention.

In more detail, Figure 1 shows the configuration of a wall-type air quality management device 100 for managing the air quality using a plant, if the person having ordinary knowledge in the technical field to which the present invention belongs, Figure 1 Reference may be made to and / or modified to infer various implementation methods (e.g., implementation methods in which some components are omitted, subdivided, or combined) for the air quality management apparatus 100, but the present invention is inferred from the above. It is made including all implementation methods, the technical features are not limited only to the implementation method shown in FIG.

Figure 1a shows the air quality management device 100 and the port module 200 is inserted into the air quality management device 100 according to the present invention, Figure 1b is a plurality of port module 200 is inserted air quality management device 100 is shown.

The port module 200 is manufactured to include a frame portion for maintaining the hexagonal structure and the receiving portion for exposing the leaf portion to the outside while receiving the leaf portion and the stem portion of the designated plant and the body portion for receiving the root portion of the plant, the air quality It is characterized in that it is inserted into the port insertion portion 105 of the management device (100). A more detailed description of the port module 200 will be described with reference to FIGS.

According to the present invention, the air quality management apparatus 100 includes a port insertion unit 105, a discharge unit 110, a housing unit 115, a fan unit 120, a light source unit 150, a water tank unit 125, and a pump unit. 130 and the water supply unit 135 may be configured.

Referring to FIGS. 1A and 1B, the port insertion unit 105 arranges and inserts M (M≥4) port modules 200 in a designated arrangement structure and inserts and fixes M (M≥4) port modules 200 in a designated arrangement structure. Dogs may be provided.

The discharge unit 110 may discharge the air inside the air quality management apparatus 100 to the outside.

The housing unit 115 may be sealed by blocking the flow of air to the outside in addition to the discharge unit 110 and the M port inserting portion 105.

The fan unit 120 generates negative pressure for introducing external air into the housing unit 115 via the M port modules 200 inserted into the M port insertion units 105. While generating, positive pressure may be generated to discharge the internal air to the outside through the discharge unit 110.

The light source unit 150 is a leaf portion of a plant accommodated in the M port module 200 inserted into the M port insertion unit 105 from the outside of the housing unit 115 to display visible light having at least one specified luminance range. You can investigate.

The water tank unit 125 may store a specified volume of water, and the pump unit 130 may pump water stored in the water tank unit 125 to a predetermined height.

The water supply unit 135 is a predetermined number of ports provided in the uppermost layer of the M port module 200 inserted into the M port insertion unit 105 by using the potential energy of the water pumped through the pump unit 130 The module 200 may drop supply a predetermined volume of water per unit time.

1A and 1B, the air quality management apparatus 100 may further include a drip tray 140 and a backflow prevention unit 145.

The drip tray 140 receives water that is discharged and dropped through a specified number of port modules 200 provided in the lowermost layer of the M port modules 200, and is transferred to the water tank unit 125. 145 prevents the backflow of the water stored in the water tank (125).

Referring to FIGS. 1A and 1B, the air quality management apparatus 100 includes a sensor unit 155 including i (i ≧ 1) sensors for sensing the quality of external air, and the sensor unit 155. The control module 160 may further include a control module 160 configured to control to emit visible light having a predetermined brightness range through the light source unit 150 based on a result of sensing the quality of the outside air.

For example, when a lot of people enter the space where the air quality management device 100 is installed to breathe and the concentration of carbon dioxide (CO2) increases (= CO2 itself is not harmful to the human body, drowsiness), plant oxygen through the photosynthesis of the plant In order to increase the emission amount, the visible light emitted from the light source unit 150 may be controlled such that the luminance reaching the leaf portion accommodated in each of the port modules 200 arranged in the designated arrangement structure is greater than or equal to the specified lux.

According to the exemplary embodiment of the present invention, the control module 160 checks whether the CO2 detection amount sensed by the sensor unit 155 exceeds a preset reference value, and the detected CO2 detection amount exceeds a preset reference value. In one case, the luminance range of visible light reaching the leaf portion of the plant, which is emitted through the light source unit 150 and received in each of the port modules 200 arranged in the designated arrangement structure, may be controlled to maintain the luminance range of 1,000 lux or more.

In addition, the control module 160 is photosynthetic retention time is emitted through the light source unit 150 is irradiated with visible light in the luminance range of 1,000 lux or more in the leaf portion of the plant accommodated in each port module 200 arranged in a specified arrangement structure Check whether the amount of CO2 detection exceeding the preset reference time or sensed by the sensor unit 155 is less than the preset reference value, and the photosynthesis holding time exceeds the preset reference time or the detected amount of CO2 detection is If it is less than the set reference value to control the luminance range of the visible light emitted through the light source unit 150 to reach the leaf portion of the plant accommodated in each port module 200 arranged in a specified arrangement structure to maintain a luminance range of 700 lux or less Can be.

Meanwhile, referring to FIGS. 1A and 1B, the air quality management apparatus 100 includes a sensor unit 155 including i (i ≧ 1) sensors for sensing the quality of external air, and the sensor unit 155. The control module 160 may control the intensity of the sound pressure or the positive pressure generated by the fan unit 120 to a predetermined intensity based on a result of sensing the quality of the outside air through the reference).

The i sensors may include a gas sensor for detecting CO 2, a gas sensor for detecting CO, a gas sensor for detecting NO, a gas sensor for detecting NO 2, a gas sensor for detecting SO 2, a gas sensor for detecting O 3, and a VOC ( One or more of VOC sensor for detecting Volatile Organic Compounds, fine dust sensor for detecting fine dust, temperature sensor for detecting temperature, humidity sensor for detecting humidity, sound sensor for detecting sound, and light sensor for detecting light intensity It may include.

2 is a view showing the configuration of a port module for air quality management according to an embodiment of the present invention.

More specifically, Figure 2 is inserted into one or more port inserting portion 105 formed on the wall (one side) of the wall-type air quality management device 100 for managing the air quality using a plant, at a predetermined blending ratio The configuration of the port module 200 containing two or more different types of designated rock granules and activated carbon, which are combined with one of ordinary skill in the art, will be described with reference to and / or modification of the present invention. Thus, various implementation methods (for example, some components may be omitted, subdivided, or combined) for the port module 200 inserted into the air quality management apparatus 100 of FIG. 1 may be inferred. The present invention includes all the implementation methods inferred above, the technical features are not limited only to the implementation method shown in FIG.

In addition, Figure 2 is shown in subdivided into Figures 2a, 2b, Figure 2c in order to recognize in more detail the configuration of the port module 200 according to the present invention, Figure 2a is a side view of the port module 200, FIG. 2B shows a front view of the port module 200 and FIG. 2C shows a plan view of the port module 200.

According to the present invention, the port module 200 may be configured to include a frame portion 205, a receiving portion 210, and a body portion 220.

Referring to Figures 2a, 2b, 2c, the frame portion 205 is made of a hexagonal structure with a hexagonal hole formed in the port insertion portion 105 formed on the wall surface of the wall-type air quality management device 100 One of the six vertices of the hexagonal structure at the time of insertion may be implemented in an arrangement structure in which one lowermost vertex is disposed in the direction of gravity and both sides are arranged parallel to the direction of gravity.

2A, 2B, and 2C, the accommodating part 210 is provided in one side direction of the frame part 205 in which the hexagonal structure hole is formed, and the lowermost vertex and both lower sides and both sides of the hexagonal structure. Ports formed on the wall surface of the wall-type air quality management device 100 to form an accommodation space in which a part of the hole area of the pentagonal cross-sectional structure including a lower vertex and at least a portion of both sides is formed in a head of ship shape. When inserted into the insertion unit 105 may be configured to be exposed to the outside of the wall surface of the air quality management apparatus 100.

According to the embodiment of the present invention, the receiving unit 210 as shown in Figures 2a and 2b, by using the negative pressure (Negative Pressure) formed in the internal space of the air quality management apparatus 100 (100) It may be configured to include a plurality of suction holes 215 for sucking the outside air into the accommodation space of the accommodation portion, wherein the air sucked through the plurality of suction holes 215 is the accommodation portion ( It may flow to the interior space of the air quality management device 100 via the accommodation space of the 210 and the accommodation space of the body portion 220.

In addition, the suction hole 115 is specified in response to the sound pressure generated through the fan unit provided in the air quality management apparatus 100 when the predetermined number of port modules 200 are inserted into the wall surface of the air quality management apparatus 100. The number of port modules 200 may be configured to include a size and number capable of introducing external air of a specified volume per unit time.

According to the method of the present invention, the receiving portion 210 may accommodate the designated n (n≥2) rock grains and activated carbons that are blended at a predetermined blending ratio, not soil. Here, the mixing ratio of the n rock pellets and activated carbon may be basically 1: 1: 1: 1: 1: 1, and the environment (eg, office, school, factory, where the air quality management apparatus 100 is installed) Depending on the type and amount of harmful substances generated in restaurants, etc., the proportion of the corresponding rock or activated carbon may be increased.

For example, the soil rich in organic matter is advantageous for plant growth, but in addition to microorganisms that are beneficial for air quality control, harmful microorganisms and pathogens floating in the air can be deposited and multiply, and thus, the present invention is suitable for managing air quality. Instead of using the soil, the rock pellets and activated carbon are used.

2A and 2C, the body portion 220 is provided in the other side surface direction of the frame portion 205 in which the hexagonal structure hole is formed, and the lowermost vertex, both lower sides and both lower vertices of the hexagonal structure. And forming a receiving space that extends a portion of the hole area of the pentagonal cross-sectional structure including at least a portion of the both sides, and aligns and drills in one or more surface areas forming the accommodation space in a direction matching the gravity direction vector component. It is provided with a plurality of discharge holes 225 and may be configured to be accommodated inside the air quality management apparatus 100 when inserted into the port insertion portion 105 formed on the wall surface of the wall-type air quality management apparatus 100.

According to the method of the present invention, the body portion 220 may also accommodate the designated n (n≥2) rock grains and activated carbons formulated at a predetermined blending ratio, not soil. Here, the mixing ratio of the n rock pellets and activated carbon may be basically 1: 1: 1: 1: 1: 1, and the environment (eg, office, school, factory, where the air quality management apparatus 100 is installed) Depending on the type and amount of harmful substances generated in restaurants, etc., the proportion of the corresponding rock or activated carbon may be increased.

Here, the n kinds of rock grains accommodated in the accommodating part 210 and the body part 220 may include elvan, pearlite, volcanic stone, and porous ceramic balls. .

In the case of the elvan, it is excellent in removing harmful substances and decomposing heavy metals, adsorbing and decomposing pollutants and heavy metals, toxic neutralization, antibacterial, insect repellent and deodorizing effect of cement, as well as controlling water quality (weak alkalizing) and It is known to act as a water purifying agent, to inhibit the antiseptic action with abundant dissolved oxygen amount, to revitalize the living body, to perform resonance, resonance, absorption and far-infrared radiation.

In the case of the pearlite, as a non-reactive material used as one of the means for improving the filtration efficiency in the water filtration operation, by forming an additional layer on the surface of the filter medium to protect the filter layer and to reduce the compression rate of the cake formed by compacting the solid material It is known to keep water flow smoothly by maintaining permeability.

In the case of the volcanic stone, one of the volcanic debris, the resistance to water is small, not easily blocked, water or air is uniformly distributed, and has the function of automatically adjusting the acidic or alkaline water to be close to neutral, and various inorganic components Due to its content, it is known to be suitable as a medium for hydroponic cultivation of plants.

In the case of the porous ceramic ball, it is a ceramic ball fired at 100 degrees or more, there is no harmful substance, high far-infrared emissivity, water-soluble natural antimicrobial agent is injected into the pores of the inside, it inhibits harmful germs to soil and animals and plants, and prevents mold and It is known to provide natural activity with filtration capacity.

In addition, the activated carbon is carbon treated with oxygen, which is opened with fine pores and is one of the most used materials for water purification filters, and has high degree of porosity and consequently high surface area which is volatile in water. It is known to make it ideal for removing contaminants adsorbed on carbon such as organic compounds, pesticides and benzene.

As such, the port module 200 according to the present invention accommodates the designated n kinds of rock grains and activated carbons, which are formulated at a predetermined blending ratio, instead of the conventionally used soils, so that the By combining the main functions to create synergy, it is possible to actively manage air quality as well as indirect air quality management using plants, so that the air quality can be managed under optimum conditions indoors.

On the other hand, according to the present invention, the n kinds of rock granules and activated carbon has an irregular shape having a diameter of 5 mm (± 2 mm), an irregular shape having a diameter of 10 mm (± 5 mm), and an irregular shape having a diameter of 20 mm (± 5 mm). It may comprise at least one or a combination of two or more of the size, the size of the irregular shape of 30mm (± 5mm) diameter.

In addition, the n kinds of rock grains and activated carbon are negative pressure generated through the fan unit 120 provided in the air quality management apparatus 100 when a predetermined number of port modules 200 are inserted into the wall of the air quality management apparatus 100. Corresponding to (Negative Pressure) it may be configured to have a size that can form a gap for introducing a predetermined volume of the outside air per unit time through the predetermined number of port modules 200. For example, the size of the n kinds of rock grains and activated carbon is not fixed, but some port modules are inserted into the air quality management apparatus 100 according to a person skilled in the art and some pressure is generated by the fan unit 120. It is obvious that it can be calculated dynamically depending on whether or not it is used.

Referring to FIGS. 2A and 2C, the plurality of discharge holes 225 provided in the body portion 220 may include gravity direction vectors on both bottom surfaces of a five-sided cross-sectional structure forming an accommodation space of the body portion 220. The gravity direction vector component may include a direction perpendicular to a lowermost corner region of the pentagonal cross-sectional structure forming an accommodation space of the body portion 220. .

On the other hand, referring to Figure 2a, the body portion 220, the water discharged through the discharge hole 225 in the outer surface area of the body portion 220 having the discharge hole 225 is a gravity direction vector component It may further include a flow path groove 230 for forming a flow path for inducing to flow in a direction matching with. Here, the flow path groove 230 may be configured to provide an uneven structure that flows along the flow path to minimize the surface tension of the water flowing to the bottom edge region of the pentagonal cross-sectional structure. For example, in the case of a port module having a cylindrical structure generally without a flow path groove 230 as in the related art, water discharged through the discharge hole 225 simply flows along the outer surface, and then aggregates downward by the surface tension and then gravity According to the present invention, a large amount of water drops at a time, so that a relatively large amount of water falls at a time, so that the "drip ~ smart" water dropping noise is often severe, but is discharged through the discharge hole 225 according to the present invention. Water moves along the flow path groove 230 in small amounts, and water reaching the lowermost corner region of the pentagonal cross-section along the flow path groove 230 is formed by the uneven structure of the flow path groove 230. The tension is disturbed, so that it is not largely aggregated and can be quietly dropped in small amounts.

On the other hand, referring to Figure 2a, the body portion 220 and the discharge hole 235 for discharging the air sucked through the suction hole 215 of the receiving portion 210 into the air quality management apparatus 100; The port module 200 may further include an induction part 245 for inducing the port module 200 to be stably inserted into the port insertion part 105 of the air quality management apparatus 100.

The discharge hole 235 is sucked through the suction hole 215 of the accommodating part 210 in both side regions or the rear region of the pentagonal cross-sectional structure forming the accommodating space of the body 220. The air passing through the accommodation space of the 210 and the accommodation space of the body portion may be discharged into the air quality management apparatus 100.

The induction part 245 is n (n ≧ 2) accommodated in the accommodation space of the accommodation portion 210 or the accommodation space of the body portion 220 during the insertion process into the port insertion portion 105 of the air quality management apparatus 100. It can provide an aspect to suppress the release of rock grains and activated carbon of the species) and to guide them to stably insert. For example, when the soil is accommodated in the port module 200, the soil is slightly viscous, so when inserted into the port insertion port of the air quality management device 100, even if it is slightly caught or tilted, the rock granules or activated carbon are viscous. Since there is no rock stem or inclined, the rock or activated carbon may fall off and fall to the floor, and the induction part 245 may be provided to prevent this.

On the other hand, referring to Figures 2a, 2b, 2c, the port module 200 according to the present invention is separated from the body portion 220 or coupled in the upper direction and the frame portion when coupled to the body portion 220 The cover part 250 of the structure is formed to match the hexagonal structure of 205 and the upper direction is opened so that the water falling in the gravity direction in the upper direction falls in the receiving space of the body portion 220 Can be configured.

Referring to FIG. 2B, when the cover portion 250 is coupled to the body portion 220, outside air passing through the hexagonal hole of the frame portion 205 is air quality in a region contacting the frame portion 205. It may be configured to include a blocking film portion 260 to suppress the direct inflow into the management device 100. Since the blocking membrane part 260 prevents the outside air from directly flowing into the air quality management apparatus 100, the outside air passes through the rocks and activated carbon of the accommodating part 210 and the body part 220. It may be introduced into the air quality management apparatus 100.

In addition, referring to FIG. 2B, the blocking membrane part 260 may include a through part 265 through which a part of the root part or the stem part of the plant accommodated in the accommodating part 210 passes in the direction of the body part 220. Can be.

On the other hand, referring to Figures 2a, 2b, 2c, the cover portion 250 may be provided with a latch portion 255 to be fixed to the body portion 220, in this case the body portion 220 The coupling part 240 coupled to the clasp part 255 of the cover part 250 may be provided when the cover part 250 is coupled.

3 is a diagram constitutively illustrating a port module manufacturing process for air quality management according to an embodiment of the present invention.

In more detail, FIG. 3 illustrates a port module 200 to be inserted into a predetermined number of pot inserting portions 105 formed on a wall surface of a wall type air management apparatus 100 that manages air quality using plants. As a structurally illustrated manufacturing method, those skilled in the art to which the present invention pertains, the process of manufacturing the port module 200 for the air quality management by referring to and / or modifying the present Figure 3 Various implementation methods may be inferred, but the present invention includes all the implementation methods inferred, and the technical features are not limited to the implementation method shown in FIG.

In particular, in order to more specifically express the manufacturing process of the port module 200 for air quality management, this drawing 3 sequentially shows the configuration of each process in FIGS. 3A to 3E, and an example through FIG. 3F. The port module is manufactured as shown in the drawing.

First, referring to FIG. 3A, the hexagonal hole is formed in a hexagonal structure and one of the six vertices of the hexagonal structure in the direction of gravity when inserted into the port insertion portion 105 formed on the wall surface of the wall-type air management device. The lowermost vertex of the frame portion 205 and the frame portion 205 for implementing the arrangement structure in which both sides are arranged parallel to the direction of gravity, and the hexagonal structure hole is provided in one side direction of the frame portion 205 formed with the hexagon A receiving portion 210 forming a receiving space extending in a leading form a partial hole region of the pentagonal cross-sectional structure including the lowermost vertex, both the lower and both lower sides of the structure, and at least a portion of the both side sides; It is provided in the other side surface direction of the frame portion 205 in which the structure hole is formed, and includes the lowermost vertex, both the lower and both lower vertices, and at least a portion of the both sides of the hexagonal structure. A body part having a plurality of discharge holes formed by forming a receiving space that extends a part of the hole region of the pentagonal cross-sectional structure and aligning in a direction matching with the gravity direction vector component in at least one surface area forming the receiving space The port module 220 including the 220 is prepared.

After the port module 200 is prepared as shown in FIG. 3a, referring to FIG. 3b, the designated n kinds of rock grains and activated carbon are blended in a predetermined mixing ratio in the accommodation space of the accommodation portion 210 and the body portion 220. To keep within the preset volume.

As shown in FIG. 3B, after the n kinds of rock grains and activated carbon are accommodated in the accommodating space of the accommodating part 210 and the body part 220, the accommodating part 210 is illustrated in FIG. 3C. ) And the designated plants are mounted on the n kinds of rock grains and activated carbon accommodated in the accommodation space of the body portion 220.

As shown in Fig. 3c, after the designated plants are placed on the n kinds of rock grains and activated carbon accommodated in the accommodating portion 210 and the body 220 of the accommodating space of the port module 200, referring to Fig. 3d, the frame The cover part 250 of the structure which is open in the upper direction is formed so as to form a structure matching the hexagonal structure of the part 205 and the water falling in the gravity direction in the upper direction falls in the receiving space of the body part 220. Coupling to the body portion 220.

After the cover part 250 is coupled to the body part 220 as shown in FIG. 3d, referring to FIG. 3e, the designated n type is blended at a predetermined blending ratio through the open structure of the cover part 250. By additionally accommodating the rock grains and activated carbon within a predetermined volume, the manufacturing of the port module 200 according to the present invention is completed as shown in FIG. 3f.

4 is an exemplary view of an air quality management apparatus according to an embodiment of the present invention.

In more detail, Figure 4 shows a port module 200 for air quality management according to the present invention and an air quality management apparatus 100 into which the port module 200 is inserted. Those skilled in the art may refer to and / or modify the drawing 4 to implement various methods of the port module 200 and the air quality management apparatus 100 (for example, some components may be omitted or configurations may be changed). Implementation method) may be inferred, but the present invention includes all the implementation methods inferred, and the technical features are not limited only to the implementation method shown in FIG.

Port module 200 according to the present invention is made of a hexagonal structure with a hexagonal hole formed in the direction of gravity of the six vertices of the hexagonal structure when inserted into the port inserting portion 105 provided in the air quality management apparatus 100 And a frame portion 205 for implementing an arrangement structure in which one lowermost vertex is disposed at both sides and parallel to the direction of gravity, and a frame portion 205 in which the hexagonal structure holes are formed. The port inserting portion 105 forms a receiving space extending from the lowermost vertex of the hexagonal structure, both lower and both lower vertices, and a partial hole area of the pentagonal cross-sectional structure including at least a portion of the both side edges in a leading shape. When inserted into the receiving portion 210 exposed to the outside of the wall surface of the air quality management device 100 and the other side surface of the frame portion 205 is formed the hexagonal structure hole of the hexagonal structure Gravity direction vector in at least one face region forming an accommodation space extending an area of a portion of a pentagonal cross-section comprising a lower vertex, both lower and both lower vertices, and at least a portion of both sides, and forming the accommodation space. It may have a plurality of discharge holes that are perforated by being aligned in a direction matching the component and may be configured as a body portion 220 accommodated in the air quality management apparatus 100 when inserted into the port inserting portion 105.

Wall-type air quality management device 100 for managing the air quality by using the plant according to the present invention, M (M ≥ 4) port module 200 arranged in a designated layout structure to insert and insert M port A part 105, a discharge part 110 for discharging the air inside the outside, and a housing part for blocking and sealing the flow of air to the outside in addition to the discharge part 110 and the M port inserting portion 105 ( 115 and the negative pressure for introducing external air into the housing 115 through the M port modules 200 inserted into the M port inserting portions 105. The fan unit 120 generates a positive pressure for discharging the internal air to the outside through the discharge unit 110, and is inserted into the M port insertion units 105 from the outside of the housing unit 115. The leaves of the plant housed in the M port modules 200 A light source unit 150 for irradiating the light ray, a water tank unit 125 for storing a specified volume of water, a pump unit 130 for pumping water stored in the water tank unit 125 to a predetermined height, and the pump Designated per unit time by the designated number of port modules 200 provided in the uppermost layer of the M port modules 200 inserted into the M port insertion unit 105 using the potential energy of the water pumped through the unit 130. It may be configured to include a water supply unit 135 for supplying a drop of water.

100: air quality management device 105: port insertion portion
110: discharge part 115: housing part
120: fan portion 125: water tank
130: pump unit 135: water supply unit
140: drip tray 145: backflow prevention
150: light source 155: sensor
160: control module
200: port module 205: frame portion
210: receiving portion 215: suction hole
220: body portion 225: discharge hole
230: Euro groove 235: discharge hole
240: coupling portion 245: induction portion
250: cover portion 255: latch portion
260: blocking film portion 265: through portion

Claims (22)

In the wall-type air quality management device that manages the air quality using plants,
M (M≥4) port modules manufactured including a frame portion for maintaining the hexagonal structure, a receiving portion for exposing the leaf portion to the outside while receiving the leaf portion and the stem portion of the designated plant and a body portion for receiving the root portion of the plant M port inserts arranged and inserted and fixed in a designated arrangement structure;
A discharge unit for discharging internal air to the outside;
A housing part which seals and seals an air flow to the outside in addition to the discharge part and the M port insertion part;
Positive pressure for discharging the internal air to the outside through the discharge portion while generating a negative pressure for introducing external air into the housing portion via the M port module inserted into the M port insertion portion ( A fan unit generating positive pressure;
A light source unit for irradiating visible light of at least one specified brightness range from the outside of the housing part to the leaf parts of the plants accommodated in the M port modules inserted into the M port insertion units;
A water tank unit for storing a specified volume of water;
A pump unit for pumping the water stored in the tank to a predetermined height; And
A water supply unit drop-supplied a predetermined volume of water per unit time to a predetermined number of port modules provided on the uppermost layer of the M port modules inserted into the M port insertion units using the potential energy of the water pumped through the pump unit; Air quality management device using a plant containing.
The method of claim 1,
Air quality management device using a plant characterized in that it further comprises a water receiving unit for receiving the water discharged through the specified number of port modules provided on the lowermost layer of the M port module delivered to the water tank unit.
The method of claim 1,
Air quality management device using a plant, characterized in that further comprises a backflow prevention unit for preventing the backflow of water stored in the tank.
The method of claim 1,
A sensor unit including i (i ≧ 1) sensors for sensing the quality of external air; And
And a control module for controlling to irradiate visible light in a specified brightness range through the light source unit based on a result of sensing the quality of the outside air through the sensor unit.
The method of claim 4, wherein the control module,
Check whether the amount of CO2 detected through the sensor unit exceeds a preset reference value,
When the detected amount of CO2 exceeds a predetermined reference value, the luminance range of visible light reaching the leaf portion of the plant, which is emitted through the light source unit and accommodated in each port module arranged in the designated arrangement structure, maintains the luminance range of 1,000 lux or more. Air quality management device using a plant, characterized in that for controlling.
The method of claim 4, wherein the control module,
The photosynthetic retention time irradiated with visible light having a luminous intensity range of 1,000 lux or more to a leaf portion of a plant accommodated in each port module arranged through a designated layout structure through the light source unit exceeds a preset reference time or is sensed through the sensor unit. Check whether the detection amount is less than the preset reference value,
When the photosynthesis holding time exceeds a predetermined reference time or when the detected amount of CO2 detection is less than a predetermined reference value, the intensity of visible light reaching the leaf portion of the plant accommodated in each port module disposed through the light source unit and arranged in the designated arrangement structure Air quality management apparatus using a plant, characterized in that to control the range to maintain a brightness range of 700 lux or less.
The method of claim 1,
A sensor unit including i (i ≧ 1) sensors for sensing the quality of external air; And
And a control module for controlling the intensity of the sound pressure or the positive pressure generated by the fan unit to a predetermined intensity based on a result of sensing the quality of the outside air through the sensor unit. Device.
The method of claim 4 or 7, wherein the i sensors,
Gas sensor to detect CO2,
Gas sensor to detect CO,
Gas sensor to detect NO,
Gas sensor to detect NO2,
Gas sensor to detect SO2,
Gas sensor to detect O3,
VOC sensor to detect VOC (Volatile Organic Compounds),
Fine dust sensor for detecting fine dust,
Temperature sensor to detect temperature,
Humidity sensor to detect humidity,
Sound sensor to detect sound,
Air quality management apparatus using a plant, characterized in that it comprises one or more of the light sensor for detecting the light intensity.
The method of claim 1,
The frame portion of the port module is made of a hexagonal structure and implements a hexagonal structure in which one lowermost vertex is disposed in the direction of gravity among the six vertices of the hexagonal structure,
The accommodating part of the port module is provided in one side direction of the frame part in which the hexagonal hole is formed to form an accommodating space having a head shape based on the lowermost vertex of the hexagonal structure, and the outer part of the housing part when inserted into the port inserting part. Exposed to
At least one body portion of the port module is provided in the direction of the other side of the frame portion formed with a hexagonal structure hole to form a receiving space of the pentagonal cross-sectional structure based on the lowest vertex of the hexagonal structure and to form the receiving space And a plurality of discharge holes which are perforated in alignment with a direction corresponding to the gravity direction vector component in the surface area, and are accommodated in the housing part when inserted into the port insertion part.
The method of claim 1, wherein the receiving portion,
Air quality management device using a plant, characterized in that it comprises a plurality of suction holes for sucking the air outside the air quality management device into the accommodation space of the receiving portion using the sound pressure formed in the interior space of the air quality management device. .
The method of claim 10, wherein the suction hole,
A size capable of introducing a specified volume of outside air per unit time through the designated number of port modules in response to the sound pressure generated through the fan unit provided in the air quality management apparatus when a predetermined number of port modules are inserted into the wall of the air quality management apparatus. Air quality management apparatus using a plant, characterized in that comprises a number.
The method of claim 1, wherein the receiving portion,
An air quality management apparatus using a plant, characterized in that a designated n (n≥2) type of rock grains and activated charcoal, which are formulated at a predetermined mixing ratio, instead of soil.
The method of claim 1, wherein the body portion,
An air quality management apparatus using a plant, characterized in that a designated n (n≥2) type of rock grains and activated charcoal, which are formulated at a predetermined mixing ratio, instead of soil.
The n type rock according to claim 12 or 13,
Elvan, Pearlite, Volcanic Stone, Porous air management system using a plant, characterized in that it comprises a porous ceramic ball.
The method according to claim 12 or 13, wherein the n kinds of rock grains and activated carbon,
Irregular shaped size 5 mm (± 2 mm) in diameter,
Irregularly shaped size with a diameter of 10 mm (± 5 mm),
Irregular shaped size with a diameter of 20 mm (± 5 mm),
Air quality management device using a plant, characterized in that it comprises at least one or a combination of two or more of the size of the irregular shape of 30mm (± 5mm) in diameter.
The method according to claim 12 or 13, wherein the n kinds of rock grains and activated carbon,
When a predetermined number of port modules are inserted into the wall of the air quality management device, the inlet air flows through the designated number of port modules in a predetermined volume in response to the sound pressure generated through the fan unit provided in the air quality management device. Air quality management device using a plant, characterized in that it comprises a size of the shape capable of forming voids.
The method of claim 1, wherein the discharge hole,
Air quality management device using a plant, characterized in that it comprises a plurality of perforated discharge holes arranged in a direction matched with the gravity direction vector component on both bottom regions of the pentagonal cross-sectional structure forming a receiving space of the body portion.
The method of claim 17, wherein the gravity direction vector component,
Air quality management device using a plant, characterized in that it comprises a direction perpendicular to the lowermost corner region of the pentagonal cross-sectional structure forming a receiving space of the body portion.
The method of claim 17, wherein the body portion,
And a flow path groove forming a flow path for inducing water discharged through the discharge hole to flow in a direction matching the gravity direction vector component in an outer surface region of the body part having the discharge hole. Air quality management device using plants.
The method of claim 1, wherein the body portion,
The air passing through the receiving space of the receiving portion and the receiving portion of the body through the suction hole in both side regions or the rear region of the pentagonal cross-sectional structure forming the receiving portion of the body portion into the air quality management apparatus. Air quality management apparatus using a plant, characterized in that further comprises a discharge hole for discharging.
The method of claim 1, wherein the port module,
Separated from the body portion or coupled in the upper direction and when coupled to the body portion forms a structure matching the hexagonal structure of the frame portion and the upper direction so that the water falling in the gravity direction in the upper direction falls in the receiving space of the body portion Air quality management apparatus using a plant, characterized in that further comprises a cover of the open structure.
The method of claim 21, wherein the cover portion,
Plants characterized in that it further comprises a blocking membrane portion to prevent the outside air flowing directly through the hole of the hexagonal structure of the preliminary portion in the area in contact with the frame portion when coupled to the body portion to the inside of the air quality management device. Air quality management device used.

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